Metabolic fingerprints:
Clues for a new kind of investigation
09.04.2010, Press releases
The old excuse, “I am only overweight because of my genes,” is suddenly gaining credibility as researchers uncover ever more evidence that the way our bodies digest and process nutrients in the food we eat is different for every person. The budding discipline of metabolomics strives to investigate these differences in a scientific manner. Nutrition scientists and food chemists at the Technische Universität München are on the front line: They have joined forces with outside experts to form the Munich Functional Metabolomics Initiative, an interdisciplinary network for driving research in this field.
When it comes to our genes, we are 99.9 percent identical.
And yet, every person looks different. But it does not end there. Recent
studies confirm that individual differences apply not only to superficial
traits – they also define our metabolism. Researchers are now asking how this
is even possible considering the pool of nearly identical genomes. Only once
the fundamental mechanisms are uncovered can conditions such as diabetes or
cardiovascular disease that stem from metabolic disorders be fully understood
and more effectively treated. Experts at the Center of Life and Food Sciences
Weihenstephan of the Technische Universität München (TUM) have given high
priority to the search for answers.
To this end the researchers have initiated a study called
HuMet. Fifteen healthy young men were closely scrutinized for four days. They
had to fast, eat and drink various types of standardized nutrition, and submit
to a variety of physical tests. All the while numerous blood, urine, and breath
samples were taken. Hannelore Daniel, professor of nutritional physiology, and
Prof. Hans Hauner, a nutritional physician at the TUM, carried out the
nutritional protocol and test procedures, while Prof. Thomas Hofmann from the
Chair of Food Chemistry and Molecular Sensory Science used the samples for a
multitude of tests using his team's high-performance analytic tools.
“In general, all people react similarly to specific
nutritional components,” says Hannelore Daniel, “but there are big differences
in their responses.” For example, when a test subject is given a certain amount
of glucose, his or her blood sugar level rises and then falls again. But even
early results of the HuMet study revealed some astonishing details: In the
beginning, on an empty stomach, the values were extremely uniform; however,
every test subject responded differently after ingesting glucose. “Obviously
all values will rise”, Daniel says. “The blood sugar level must go up. But it
is very interesting to observe the differences in the way the levels rise and
fall off again. It took four hours for the test subjects' blood sugar levels to
come back into alignment with each other.”
Daniel describes our metabolism as a mechanism that can be
pushed and pulled like the bellows of an accordion. One thing the researchers
want to determine is how wide the range is, and modern methods of
high-performance analytics make that possible. “The HuMet study actually gave
the impetus for the entire field of research,” TUM food chemist Thomas Hofmann
is pleased to note. “All researchers in greater Munich interested in advancing
the field of metabolomics, for example our colleagues from the Helmholz Zentrum
München, are collaborating with us in the Munich Functional Metabolomics
Initiative.” All participating researchers received a portion of all plasma and
urine samples to evaluate them using their own special measuring methods. Prof.
Hofmann’s team relied primarily on the methods of liquid chromatography-tandem
mass spectroscopy and NMR spectroscopy.
“We need to develop the methods further to do justice to the
complexity of the body’s metabolism. Today, we are at a level comparable to
that of digital cameras in the 1980s,” says Hofmann. “We must increase the
resolution of our analytical camera to obtain a sharp image of all metabolic
by-products.” And if we want to describe metabolic dynamics next, we will need
to make a short movie. “For this we want to automate our procedure so that it
will deliver a large number of high-resolution images over a short period of
time. These can then be combined into a sequence, analogous to a flip-book.”
Once this becomes possible, the researchers will be able to
look deep into metabolic processes. Their biggest hope: that metabolomics will
one day enable custom-tailored therapies for people with metabolic disorders
and nutrition plans for people wanting to lose weight.
Contact:
Prof. Hannelore Daniel
Molecular Nutrition Unit
Technische Universität München
85350 Freising-Weihenstephan
Tel.: 08161 / 71 - 3400
E-mail: daniel@wzw.tum.de
http://www.wzw.tum.de/nutrition
Prof. Thomas Hofmann
Chair of Food Chemistry and Molecular Sensory Science
Technische Universität München
85350 Freising-Weihenstephan
Tel.: 08161 / 71 - 2902
E-mail: thomas.hofmann@wzw.tum.de
http://www.molekulare-sensorik.de
Kontakt: presse@tum.de
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